Substrates

ABSTRACT

The invention relates to improvements in substrates and in particular to new substrates having magnetic and visual security features, which provide security against imitation. A security substrate comprising a transparent polymer carrier layer bearing indicia formed from a plurality of opaque and non-opaque regions and a clear and transparent magnetic layer supported by the carrier layer containing a distribution of particles of a soft magnetic material of a size and distributed in a concentration at which the magnetic layer remains clear and transparent.

The invention relates to improvements in substrates and in particular tonew substrates having magnetic and visual security features, whichprovide security against imitation.

It is widely known to use in banknotes and other security documentssecurity elements, such as security threads or strips. These threads arepartially or wholly embedded in a paper or plastic substrate, andgenerally provide different viewing conditions depending on whether thesecurity document is viewed in transmitted or reflected light.

EP-A-319157, for example, describes a security element made from atransparent plastic film provided with a continuous reflective metallayer, such as aluminium, which has been vacuumed deposited on the film.The metal layer is partially demetallised to provide clear demetallisedregions which form indicia. When wholly embedded within a papersubstrate the security element is barely visible in reflected light.However, when viewed in transmitted light the indicia can be clearlyseen highlighted against the dark background of the metallised area ofthe thread and adjacent areas of the paper. Such threads can also beused in a security document provided with repeating windows in at leastone surface of the paper substrate at which the security thread isexposed. A security document of this type, when viewed in transmittedlight, will be seen as a dark line with the indicia highlighted. Whenviewed in reflected light on the windowed side, the bright shinyaluminium portions are readily visible in the windows. This thread hasbeen highly successful within the market place and is supplied under thetrade mark Cleartext®.

For a number of years banknote issuing authorities have had an interestin combining both the public recognition properties of Cleartext® withthe covert properties of a machine readable feature. To this end it ispreferable to utilise machine readable features that can be read usingdetectors already available to the banknote issuing authorities.Examples of such machine readable devices are described in WO-A-92/11142and EP-A-773872.

The security device of WO-A-92/11142 is an attempt to provide thiscombination. A security device conforming to this specification has beenused commercially with some success. A central region of the securitydevice has a metallic appearance with clear regions forming characters;on either side of this central strip in the width direction, there arelayers of magnetic material with obscuring coatings to provide thenecessary magnetic component. This is, however, a generallyunsatisfactory means of achieving the combination of the appearance ofCleartext® with the required magnetic properties. The magneticproperties are satisfactory, but the requirement to place the magneticlayers on either side of a central region means that the latter must berelatively narrow with respect to the overall thread width and resultsin characters which are small, typically 0.7 mm high, and therefore noteasily legible. Additionally, the structures of the devices described inWO-A-92/11142 are very complex and present substantial lateralregistration problems in depositing the various layers; amisregistration of even 0.1 mm or so can allow the presence of the darkmagnetic oxide to be apparent to the naked eye, thus revealing itspresence and seriously detracting from the aesthetic appearance of thesecurity thread.

A more satisfactory solution, from the processibility, ease of characterrecognition and aesthetics points of view, would be to manufacture adevice of the kind described in EP-A-0319157 from a metal which isitself magnetic such that the size of the characters and ratio ofcharacter height:thread width of the Cleartext® product is maintained,whilst providing direct compatibility with existing magnetic threaddetectors. One means of achieving this is disclosed in ResearchDisclosure No. 323 of March 1991. In this Research Disclosure, amagnetic material is deposited onto a flexible substrate by vacuumsputtering or other known techniques; the non-metallised regions arecreated by selective printing of a resist layer and subsequent chemicaletching. The disclosed magnetic materials may be nickel, cobalt, iron oralloys thereof with a preferred combination of cobalt:nickel in theratio 85:15%. The disadvantage of this method is that vacuum depositionof cobalt:nickel to the necessary thickness is a relatively slow processand somewhat wasteful of cobalt, an expensive material. Furthermore,subsequent to this vacuum deposition process, further significantprocessing is required to etch the characters. The resultant product istherefore relatively expensive.

A further alternative approach is described in EP-A-773872 wherein amagnetic metal is deposited on a film of polymeric substrate as thesubstrate passes through a solution containing the magnetic metal, and apreparatory operation is carried out on a surface of the substrate priorto immersion of the substrate in the solution. The preparatory operationensures that magnetic metal is deposited on the substrate in a chosenpattern such that when the security product is produced from the film bycutting the film, the magnetic metal on the security thread has aspecific pattern and provides both a visual discernible security featureand a magnetically detectable security feature. This method produces asecurity thread with satisfactory visual and machine readablecharacteristics but the manufacture is not straight forward and iscostly.

One further approach is detailed in WO-A-9928852. Here the securitydevice includes a carrier substrate, a metallic layer disposed on thecarrier substrate, and a magnetic layer disposed on the metallic layerin substantial registration with at least a portion of the metalliclayer, thereby providing both metallic security features and magneticsecurity features. The metallic layer and the magnetic layer also formgraphic or visually identifiable indicia on the carrier substrate toprovide a visual security feature. According to one method, the metalliclayer is applied to the carrier substrate, the magnetic layer is appliedto the metallic layer, and the layers are etched to form the graphicindicia. The magnetic layer can, in one embodiment, include a magneticchemical resist that is printed on the metallic layer in the form of thegraphic indicia. This method again produces a security device withacceptable visual and magnetic characteristics but again has a high costwith regard to processing and production.

The present invention therefore seeks to provide a security substratethat may be slit into security threads for partially or wholly embeddinginto paper or polymer which has acceptable magnetic and visualcharacteristics as described above and also greatly simplifies themanufacturing process. Such a simplification produces costs savings forboth manufacture and materials as levels of spoil are greatly reduced.

The invention therefore provides a security substrate comprising atransparent polymer carrier layer bearing indicia formed from aplurality of opaque and non-opaque regions and a clear transparentmagnetic layer supported by the carrier layer containing a distributionof particles of a magnetic flake nickel material of a size anddistributed in a concentration at which the magnetic layer remains clearand transparent.

The advantage of using a clear magnetic layer means that this type ofmagnetic feature can be incorporated into existing designs of securityelements (threads) without affecting their visual appearance. Thisavoids the need to retrain the public and other handlers in recognitionof the security features of security documents incorporating suchelements. It thus allows for a seamless introduction of a magneticfeature, without the need to withdraw existing security documents. Bothvariations, with and without the magnetic feature, can be used side byside without confusion occurring.

Additionally, counterfeiters are not likely to be aware of the existenceof the transparent magnetic features and therefore are less likely totry to include one in any counterfeits, thus making it easier to detectcounterfeits.

A preferred embodiment of the present invention will now be described byway of example only, with reference to the accompanying drawings inwhich:

FIGS. 1, 2, and 3 are cross-sectional side elevations of a substrateaccording to the present invention;

FIG. 4 is cross-sectional side elevation of an alternative substrate tothat shown in FIG. 1;

FIGS. 5, 6, and 7 are cross-sectional side elevations of furtheralternative embodiments of the substrate of FIG. 1 with an adhesivelayer applied, for use in tear tapes;

FIGS. 8 and 9 are cross-sectional side elevations of other alternativesubstrates to that shown in FIG. 1 with an adhesive applied to thedemetallised surface, for use as a tamper evident tear tape;

FIGS. 10, 11, and 12 are cross-sectional side elevations of furtheralternative substrates to that shown in FIG. 1 incorporating a highreflective index or polymer liquid crystal layer;

FIGS. 13, 14, and 15 are cross-sectional side elevations of furtheralternative substrates to that of FIG. 1, with an HRI or polymer liquidcrystal layer, no metallisation and including a print feature;

FIGS. 16, 17, 18 and 19 are cross-sectional side elevations of furtheralternative substrates to those shown in FIGS. 13, 14 and 15, but withthe addition of a demetallised layer;

FIGS. 20, 21, 22 and 23 are cross-sectional side elevations of analternative substrate to that shown in FIGS. 16, 17, 18 and 19 with thehigh refractive index or polymer liquid crystal layer replaced by asecond clear polymer layer;

FIGS. 24, 25, 26 and 27 are cross-sectional side elevations of analternative substrate to that shown in FIG. 20 but with the printfeatures located within the demetallised region;

FIGS. 28 to 35 are cross-sectional side elevations of furtheralternative substrates incorporating optically variable devices;

FIG. 36 is a cross-sectional side elevation of an alternative substrateto that of FIG. 2, but with two demetallised layers, one on either sideof the transparent magnetic media containing layer; and

FIGS. 37 and 38 are cross-sectional side elevations of furtheralternative substrates which are coded.

The present invention makes use of transparent magnetic materials thatare now available from a number of suppliers. In the most basic formsuch transparent magnetic media comprises a polymeric film in which havebeen suspended magnetic particles of flake nickel magnetic material. Theparticles themselves are not colourless, but the degree of concentrationis such as to allow the polymeric film to remain clear and transparent.Various other forms of transparent magnetic media are described in theprior art any of which would be suitable for the present application. Inparticular, the wider the thread, the lower the concentration ofmagnetic particles is required for accurate machine detection, due tothe fact that the signal recovery is considerably differentiated fromthe normal cash processing system noise.

FIGS. 1 and 4 illustrate two embodiments of a substrate according to thepresent invention. In FIG. 1 the substrate comprises a transparentpolymer carrier layer (1) and a clear transparent, magnetic layer (2)formed from magnetic particles which are suspended in a varnish which isprinted or coated onto the carrier layer (1). The size and distributionof the particles is controlled so that the thickness of the magneticlayer (2) is irrelevant. The size of the particles may vary fordifferent materials, examples of which are listed below. Although largerparticles of these magnetic materials are lighter than smallerparticles, the size must also be selected to enable painting or coatingof the varnish containing the particles.

The invention requires the use of flake nickel magnetic materials, whichhave little or no magnetic remanence in the absence of an appliedmagnetic field, and preferably a coercivity of less than 100 oersteds,and more preferably less than 50 oersteds.

Suitable materials must have a sufficiently high saturationmaqnetisation. Flake nickel materials can be used with surprisingadvantages. These materials have a small coercivity and a highlydetectable remanence, and still give a transparent film. As is wellknown, the thinner and more flake like the particles, the greater theanisotropy and therefore the resulting covercivity and remanence. Theremanence is high enough to be detectable on inductive machine readheads, which are the older more well known machines, without the needfor the newer magnet-resistive heads.

Suitable varnishes include 1462 from Luminescence, VHL 31534 from SunChemicals or 31833XSN, 20784XSN and 90838XSN, all from Coates Lorilleux.The carrier layer (1) may be PET, BOPP or another suitable polymer.

Alternatively, as shown in FIG. 4, the magnetic particles may beincorporated in the polymer layer (6) itself. From herein it should beappreciated that the use of a coated polymer layer (1) or a polymerlayer (6) containing the magnetic particles are interchangeable withinall the described embodiments.

The substrate is provided with indicia formed from a plurality of opaqueand non-opaque regions, which may be metallised, demetallised, printedor provided in another manner. The magnetic layer (2) may be locatedbelow the indicia, over the indicia, or in a full or partial layer whichmay or may not be in register with the indicia.

The transparent magnetic layer (2,6) is preferably vacuum metallised andthen selectively demetallised in a known manner to provide the indicia,which are formed by metallised regions (3) and demetallised regions (4).

It should be noted that any magnetic print feature/code used inconjunction with demetallisation does not need to be registeredtherewith.

The resulting substrate can therefore have both public (overt) andmachine readable (covert) features.

A further polymer layer (5) (12 μm polyester for example) may optionallybe laminated to the aforementioned substrate to cover the metallised anddemetallised regions (3,4) to improve its durability. The additionalpolymer layer (5) may or may not contain magnetic particles dependingupon requirements.

The thus formed substrate may then be slit in register to form thinstrips suitable for inclusion as security threads into banknotes orother security documents, such as credit, debit and other cards. Typicalwidths for security threads lie in the range 0.5 mm to 50 mm, and morepreferably 1 mm to 10 mm. The use of the substrate of the presentinvention is not merely limited to use as security threads, but may alsobe used to provide other security media such as secure tear tapes forbrand protection, or a secure substrate for the manufacture ofholograms, labels, transfers, hang tags, certificates, bonds, cheques,banknotes and other documents of value. In particular the substrate isparticularly suitable for manufacturing plastic banknotes. When utilisedas a substrate for such applications it is envisaged that an opaque inkreceptive coating be applied over at least part of the substrate.

The secure substrate described above can be further enhanced as will beunderstood by those skilled in the art. Such enhancements include, butare not limited to, the application of luminescent, thermochromic and,photochromic materials and embossed optically variable devices. Examplesof how this might be achieved are described in EP-A-319157,GB-A-2274428, WO-A-00/54985, and WO-A-00/39391.

The use of a clear magnetic layer (2,6) means that the effects of suchadditional features are not obscured or interfered with by any colouringin the magnetic layer (2,6). With reference to the use of visiblepigmentation or dyes, this allows the full spectrum of colours to beexhibited. Known systems using hard magnetics are tinted, often orangeor brown, which prevents the use of yellow or other lightly colouredeffects. This is particularly pronounced when using luminescentmaterials.

It would also be possible to use the invention to provide a codedsecurity thread. Such a thread may use interspersed magnetic and textregions, or it could incorporate a coded format, such as that describedin EP-A-407550 or a fixed length or code or use special thickness orcoercivity variants to achieve a code. Fixed length coding is aspatially variant of magnetic print with a repeat length equal for, say,all denominations of a particular currency or security document set. Theadvantage to this type of coding is that the clocking of the code duringread is easily established without the need for clocking bits in thecode format. Additionally, a magnetic layer could be coated onto atleast a part of the substrate to provide a magnetic code. Saidadditional magnetic layer could contain a magnetic material of differentcoercivity to that of the substrate film.

The invention will now be described in more detail by reference to thefollowing examples.

EXAMPLE 1

In a first example, as shown in FIG. 1, the polymer carrier (1) isprovided by a 12 μm standard polyester film which is coated at a coatweight of 2 gsm with a varnish (2) containing 0.1-50%, more preferably1-30%, by weight of magnetic material. The lower range of loading can beused where more sophisticated detection equipment is available. Ontothis carrier (1) a metallic reflection-enhancing layer, such asaluminium, is applied, although other metals such as copper could beused. This metallic layer is printed with a resist layer definingindicia and is then exposed to a caustic etch solution which removes themetal not protected by the resist. The caustic solution is washed awayto reveal metallised regions (3) and demetallised regions (4), definingindicia. Alternatively any of the known methods for demetallisationcould be used. An additional layer (5) of 12 μm polyester may then beapplied using a layer of adhesive to improve durability of thesubstrate. The thus formed substrate may then be slit in register toform security threads for inclusion into paper or polymer as describedin EP-A-59056 and GB-A-0111452.9 respectively. Where the substrate isused to form security threads a further layer of adhesive is preferablyapplied to one or both sides of the substrate to ensure secure locationof the thread within a sheet of paper. In this, and other examples,further barrier layers are preferably provided on either side of themetallic layer to prevent environmental attack.

Potential alternative constructions are shown in FIGS. 2 and 3. In boththese examples a metallised polymer film e.g. 12 μm metallised Type Sfrom DuPont is demetallised as described above prior to application ofthe magnetic varnish layer. FIG. 2 shows the varnish layer applied ontothe demetallised surface and FIG. 3 shows the varnish layer applied onthe opposite side to the demetallised layer.

EXAMPLE 2

In a second example, as shown in FIG. 5, a layer of a pressure sensitiveor hot melt adhesive (7) is subsequently applied to either of thepolymer layers (1, 5) of the substrate of Example 1, and strips of thesubstrate may be used as a tear tape for secure packaging.

FIGS. 6 and 7 show alternative constructions with the varnish layerapplied onto the demetallised layer on the opposite side of thedemetallised layer.

EXAMPLE 3

As a further alternative a layer of pressure sensitive or hot meltadhesive (7) may be applied to the partially metallised surface (3,4) asshown in FIG. 8. This provides the additional benefit that tapes madefrom the substrate now show some tamper evident properties. When such atape is removed from the packaging or substrate the metal region (3)will be irreversibly removed to clearly illustrate tampering. A suitablepressure sensitive adhesive would be Indatex SE 5219 (applied at between1 gsm-20 gsm, and more preferably at 8 gsm).

FIG. 9 shows an alternative construction with the varnish layer appliedto the opposite side of the demetallised layer.

EXAMPLE 4

In this example the magnetic particles have been included as part of thepolymer carrier layer (6), as shown in FIG. 4. In a typical example,0.1-50% by weight of magnetic material would be included in thepolyester, which is preferably a 12 μm film, or more preferably 1-30% byweight of magnetic material. The lower range of loading can be usedwhere more sophisticated detection equipment is available. The polymercan then be further processed as described above.

EXAMPLE 5

As an alternative a high refractive index (HRI) layer (8) such as ZnS ora polymer liquid crystal layer can be applied in preference to or inaddition to the partial metal layer (3,4) as shown in FIG. 5 to providean iridescent effect in the metallic regions (3). However, a dark orblack background layer will need to be located behind any liquid crystallayer to cause the colourshift effect.

FIGS. 11 and 12 show alternative constructions where the varnish layeris applied onto the partial metal layer or onto the opposite side to thepartial metal layer.

EXAMPLE 6

If no metal layer is present, opaque inks may be printed in selectedregions (9) onto the transparent magnetic media containing layer (2,6)to form the indicia, as shown in FIGS. 13 to 15, using any of thetraditional print processes such as gravure, flexo, intaglio, litho,thermal transfer, dye diffusion and so forth. Additional security can beachieved using iridescent, luminescent (visible or invisible indaylight), optically variable, liquid crystal, thermochromic orphotochromic inks in conjunction with, or as an alternative to, theopaque ink. It is preferable that such inks be applied in selectedregions of the substrate so as to overlie or highlight the indicia, oreven provide additional indicia. Optionally an HRI or polymer liquidcrystal layer (8) may be provided.

EXAMPLE 7

The inks described above may also be applied in selected regions (9) inaddition to demetallised indicia to further enhance security as shown inFIGS. 16 to 19 with the HRI or polymer liquid crystal layer (8) applied.thereover, or with a second polymer layer (5) as shown in FIGS. 20 to23.

EXAMPLE 8

In this example, as shown in FIGS. 24 to 27 the printed regions (9) arelocated within the demetallised regions 4, but not wholly filling them.

EXAMPLE 9

It is also possible to produce a variant of the invention incorporatingan optically variable device such as a hologram, Kinegram or Exelgram.Here an additional embossing lacquer (10) is applied on to the substrateand embossed to provide an embossed surface (11). The reflectionenhancing layer may be metal, as shown in FIGS. 28 to 31, or an HRIlayer, as shown in FIGS. 32 to 34.

FIGS. 28 to 31 show alternative constructions for the optically variabledevice utilising a metallic reflection enhancing layer. FIGS. 32 to 34show alternative constructions for utilising the HRI reflectionenhancing layer.

EXAMPLE 10

FIG. 35 illustrates an alternative construction whereby the coated film(1,2) is metallised and, selectively demetallised. An embossing lacquer(10) is applied, which is then embossed. An optional protective polymerlayer(s) is applied to the embossed surface (11).

EXAMPLE 11

FIG. 2 illustrates a further alternative construction, which is avariant of that shown in FIG. 1, whereby the polymer carrier layer (1)has a metal layer applied thereto which is partially demetallised toform a partially metallised surface (3,4). The varnish (2) containingthe magnetic material is then applied to the partially metallisedsurface (3,4). An additional protective layer (5) may then applied overthe layer of varnish (2). Alternatively, the varnish (2) may first beapplied to the protective layer (5) and this construction laminated tothe partially demetallised structure (3,4).

EXAMPLE 12

In this example, as illustrated in FIG. 36, the substrate has twopartially metallised layers (3,4). This is achieved by partiallydemetallising the first carrier layer (1) and, in a separate process,partially demetallising a second additional carrier layer (5). Themagnetic material containing varnish (2) is applied to the partiallymetallised surface (3,4) of the first layer (1) and a laminatingadhesive (12) applied to enable the second layer (5) with itsdemetallised surface (3,4) to be adhered to the first layer (1).

EXAMPLE 13

This is an example of a coded thread as mentioned previously and asillustrated in FIG. 37. In this example an additional magnetic layer(10) is applied to the transparent magnetic media containing layer (2).The additional magnetic layer (10) is preferably discontinuous and alsotransparent, but incorporates a material of differing coercivity to thatof layer (2). Although it is preferred that the layer (10) istransparent, a non-transparent magnetic material may be used in layer10. The additional layer (10) may also comprise several differentmagnetic materials printed sequentially to define a code, eitherabutting or overlapping to form a continuous layer.

EXAMPLE 14

This is a further example of a coded substrate, as illustrated in FIG.38, in which the magnetic material containing varnish (2) is applied ina discontinuous manner to define a code. The code may be printed withseveral materials having different coercivities. In this example theneed for an additional magnetic layer as described in Example 13 isremoved. However, as with the previous examples, where using materialsof differing coercivities, these can be printed in sequence eitherabutting or overlapping to form a continuous layer. In this Examplenumeral (13) denotes an uncoated magnetic region. In an alternativeembodiment, the code does not need to be in register with the indicia.

In all the aforementioned examples it should be noted that, as mentionedin conjunction with Example 34, the demetallised construction consistingof the carrier layer (1) and partially metallised surface (3,4) can beformed separately from the transparent magnetic construction comprisingthe protective layer (5) with the magnetic material containing varnish(2) and then laminated together using a suitable adhesive.

1. A security substrate comprising a transparent polymer carrier layerbearing indicia formed from a plurality of opaque and non opaque regionsand a clear transparent magnetic layer supported by the carrier layercontaining a distribution of particles of a flake nickel magneticmaterial, having a low coercivity of less than 100 oersteds and a highlydetectable remanence, of a size and distributed in a concentration atwhich the magnetic layer remains clear and transparent.
 2. A securitysubstrate as claimed in claim 1 in which the transparent magnetic layercomprises a varnish in which are suspended the magnetic particles.
 3. Asecurity substrate as claimed in claim 1 in which the transparentmagnetic layer lies between the carrier layer and the indicia.
 4. Asecurity substrate as claimed in claim 1 in which the indicia are formedon the carrier layer and the transparent magnetic layer covers theindicia.
 5. A security substrate comprising a clear transparent polymercarrier layer, bearing indicia formed from a plurality of opaque and nonopaque regions, which carrier layer contains a distribution of particlesof a soft magnetic material of a size and distributed in a concentrationat which the carrier layer remains clear and transparent.
 6. A securitysubstrate as claimed in claim 1 or claim 5 further comprising anadditional layer of a transparent polymer laminated to the magneticlayer and/or indicia.
 7. A security substrate as claimed in claim 1 orclaim 5 further comprising a layer of adhesive applied to at least oneside of the substrate.
 8. A security substrate as claimed in claim 1 orclaim 5 in which a layer of adhesive overlies the indicia.
 9. A securitysubstrate as claimed in claim 1 or claim 5 further comprising a layer ofhigh refractive index material.
 10. A security substrate as claimed inclaim 1 or claim 5 in which the indicia are provided by partiallydemetallising a metal layer, with remaining metal forming the opaqueregions and the demetallised regions forming the non opaque regions. 11.A security substrate as claimed in claim 1 or claim 5 in which theindicia are printed.
 12. A security substrate as claimed in claim 1 orclaim 5 further including additional printed regions formed from one ormore inks having iridescent, luminescent, optically variable, liquidcrystal, thermochromic and/or photochromic properties.
 13. A securitysubstrate as claimed in claim 1 or claim 5 comprising indicia providedby demetallised and metallised regions and printed indicia.
 14. Asecurity substrate as claimed in claim 13 in which the printed indiciaoverlie at least some of the metallic regions.
 15. A security substrateas claimed in claim 13 in which the printed indicia lie within thedemetallised regions.
 16. A security substrate as claimed in claim 1 orclaim 5 further comprising an optically variable device.
 17. A securitysubstrate as claimed in claim 16 in which the optically variable deviceis formed by embossing a layer of embossing lacquer.
 18. A securitysubstrate as claimed in claim 16 in which the embossing lacquer liesbetween the magnetic layer and the indicia.
 19. A security substrate asclaimed in claim 17 in which the embossing layer lies between thetransparent magnetic layer and a layer of high refractive index.
 20. Asecurity substrate as claimed in claim 17 wherein the embossing layeroverlies the indicia.
 21. An elongate security element made by the stepof slitting the substrate as claimed in claim 1 or claim 5 in registerwith the indicia.
 22. A security document comprising a paper or polymersubstrate incorporating a security thread as claimed in claim 21.